Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

doi:10.1088/1674-1056/acfaf8

中国物理B ›› 2024, Vol. 33 ›› Issue (1): 10703-10703.doi: 10.1088/1674-1056/acfaf8

Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

Xian-Jie Zheng(郑先杰), Meng Ding(丁萌), Liao-Xue Liu(刘辽雪), Lu Wang(王璐), and Yu Guo(郭毓)^†

School of Automation, Nanjing University of Science and Technology, Nanjing 210094, China

收稿日期:2023-07-18 修回日期:2023-08-22 接受日期:2023-09-19 出版日期:2023-12-13 发布日期:2023-12-28
通讯作者: Yu Guo E-mail:guoyu@njust.edu.cn
基金资助:
Project supported by the National Natural Science Foundation of China (Grant No. 61973167) and the Jiangsu Funding Program for Excellent Postdoctoral Talent.

Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

Xian-Jie Zheng(郑先杰), Meng Ding(丁萌), Liao-Xue Liu(刘辽雪), Lu Wang(王璐), and Yu Guo(郭毓)^†

School of Automation, Nanjing University of Science and Technology, Nanjing 210094, China

Received:2023-07-18 Revised:2023-08-22 Accepted:2023-09-19 Online:2023-12-13 Published:2023-12-28
Contact: Yu Guo E-mail:guoyu@njust.edu.cn
Supported by:
Project supported by the National Natural Science Foundation of China (Grant No. 61973167) and the Jiangsu Funding Program for Excellent Postdoctoral Talent.

摘要/Abstract

摘要： Continuum robots with high flexibility and compliance have the capability to operate in confined and cluttered environments. To enhance the load capacity while maintaining robot dexterity, we propose a novel non-constant subsegment stiffness structure for tendon-driven quasi continuum robots (TDQCRs) comprising rigid-flexible coupling subsegments. Aiming at real-time control applications, we present a novel static-to-kinematic modeling approach to gain a comprehensive understanding of the TDQCR model. The analytical subsegment-based kinematics for the multisection manipulator is derived based on screw theory and product of exponentials formula, and the static model considering gravity loading, actuation loading, and robot constitutive laws is established. Additionally, the effect of tension attenuation caused by routing channel friction is considered in the robot statics, resulting in improved model accuracy. The root-mean-square error between the outputs of the static model and the experimental system is less than 1.63% of the arm length (0.5 m). By employing the proposed static model, a mapping of bending angles between the configuration space and the subsegment space is established. Furthermore, motion control experiments are conducted on our TDQCR system, and the results demonstrate the effectiveness of the static-to-kinematic model.

关键词: static-to-kinematic modeling scheme, tendon-driven quasi continuum robot, nonconstant subsegment stiffness, tension attenuation effect

Abstract: Continuum robots with high flexibility and compliance have the capability to operate in confined and cluttered environments. To enhance the load capacity while maintaining robot dexterity, we propose a novel non-constant subsegment stiffness structure for tendon-driven quasi continuum robots (TDQCRs) comprising rigid-flexible coupling subsegments. Aiming at real-time control applications, we present a novel static-to-kinematic modeling approach to gain a comprehensive understanding of the TDQCR model. The analytical subsegment-based kinematics for the multisection manipulator is derived based on screw theory and product of exponentials formula, and the static model considering gravity loading, actuation loading, and robot constitutive laws is established. Additionally, the effect of tension attenuation caused by routing channel friction is considered in the robot statics, resulting in improved model accuracy. The root-mean-square error between the outputs of the static model and the experimental system is less than 1.63% of the arm length (0.5 m). By employing the proposed static model, a mapping of bending angles between the configuration space and the subsegment space is established. Furthermore, motion control experiments are conducted on our TDQCR system, and the results demonstrate the effectiveness of the static-to-kinematic model.

Key words: static-to-kinematic modeling scheme, tendon-driven quasi continuum robot, nonconstant subsegment stiffness, tension attenuation effect

中图分类号: (Computer modeling and simulation)

07.05.Tp

07.07.Tw (Servo and control equipment; robots) 45.20.D- (Newtonian mechanics)

Xian-Jie Zheng(郑先杰), Meng Ding(丁萌), Liao-Xue Liu(刘辽雪), Lu Wang(王璐), and Yu Guo(郭毓). Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness[J]. 中国物理B, 2024, 33(1): 10703-10703.

参考文献

[1] Ba W M, Dong X, Mohammad A, Wang M F, Axinte D and Norton A 2021 IEEE/ASME Trans. Mechatronics 26 3010
[2] Mohammad A, Russo M, Fang Y H, Dong X, Axinte D and Kell J 2021 IEEE Robot. Autom. Lett. 6 7493
[3] Wang M Y, Du L, Yuan J J, Ma S G and Bao S 2021 IEEE International Conference on Robotics and Biomimetics (ROBIO), December 27-31, Sanya, China, p. 74
[4] Müller D, Veil C, Seidel M and Sawodny O 2020 Mechatronics 70 102418
[5] Dupont PE, Simaan N, Choset H and Rucker C 2022 Proc. IEEE Inst. Electr. Electron. Eng. 110 847
[6] Peng Y, Liu Y G, Yang Y, Liu N, Sun Y, Liu Y Y, Pu H Y, Xie S R and Luo J 2019 Mechatronics 60 56
[7] He B, Zhang C H and Ding A 2017 Chin. Phys. B 26 126102
[8] Rus D and Tolley M T 2015 Nature 521 467
[9] Hemami A 1985 Robotics 1 27
[10] Wooten M B and Walker I D 2022 IEEE Robot. Autom. Lett. 7 10136
[11] Yuan H and Li Z 2018 Robot. Comput.-Integr. Manuf. 49 240
[12] Mo H J, Wei R F, Ouyang B, Xing L X, Shan Y H, Liu Y H and Sun D 2021 IEEE Robot. Autom. Lett. 6 1074
[13] Wang Q, Yong Y Q and Bai Z M 2022 Chin. Phys. B 31 128801
[14] Uppalapati N K and Krishnan G 2021 J. Mech. Robot. 13 011010
[15] Qin L, Liang X Q, Huang H, Chui C K, Yeow R C and Zhu J 2019 Soft Robot. 6 455
[16] Tamadon I, Huan Y, de Groot A G, Menciassi A and Sinibaldi E 2020 Int. J. Med. Robot. Comput. Assist. Surg 16 e2072
[17] Yukisawa T, Ishii Y, Nishikawa S, Niiyama R and Kuniyoshi Y 2017 IEEE International Conference on Robotics and Biomimetics (ROBIO) December 5-8, Macau, Macao, p. 2303
[18] Sui D B, Zhao S K, Wang T S, Liu Y B, Zhu Y H and Zhao J 2022 J. Bionic Eng.
[19] Xu K and Simaan N 2010 J. Mech. Robot. 2 011006
[20] Zhao B, Zhang W H, Zhang Z Y, Zhu X Y and Xu K 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) October 01-05, Madrid, Spain, p. 7492
[21] Yeshmukhametov A, Koganezawa K and Yamamoto Y 2019 Robotics 8 51
[22] Wang M F, Dong X, Ba W M, Mohammad A, Axinte D and Norton A 2021 Robot. Comput.-Integr. Manuf. 67 102054
[23] Li M H, Kang R J, Geng S N and Guglielmino E 2018 Trans. Inst. Meas. Control. 40 3263
[24] Barrientos-Diez J, Dong X, Axinte D and Kell J 2021 Robot. Comput.-Integr. Manuf. 67 102019
[25] Della Santina C, Bicchi A and Rus D 2020 IEEE Robot. Autom. Lett. 5 1001
[26] Greigarn T and Çavuşoǧlu M C 2014 IEEE/RSJ International Conference on Intelligent Robots and Systems September 14-88, Chicago, IL, USA, p. 3476
[27] Jones B A, Gray R L and Turlapati K 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems October 10-15, St. Louis, MO, USA, p. 2659
[28] Chen Y Y, Wu B B, Jin J B and Xu K 2021 IEEE Robot. Autom. Lett. 6 1590
[29] Renda F, Boyer F, Dias J and Seneviratne L 2018 IEEE Trans. Robot. 34 1518
[30] Grazioso S, Di Gironimo G and Siciliano B 2019 Soft Robot. 6 790
[31] Venkiteswaran V K, Sikorski J and Misra S 2019 Mech. Mach. Theory 139 34
[32] Thuruthel T G, Falotico E, Manti M, Pratesi A, Cianchetti M and Laschi C 2017 Soft Robot. 4 285
[33] Giorelli M, Renda F, Calisti M, Arienti A, Ferri G and Laschi C 2015 IEEE Trans. Robot. 31 823
[34] Elgeneidy K, Lohse N and Jackson M 2018 Mechatronics 50 234
[35] Lynch K M and Park F C 2017 Modern Robotics (Cambridge:Cambridge University Press) p. 118
[36] Keller S G and Gordon A P 2011 Strain Anal. Eng. Des 46 405
[37] Krogius M, Haggenmiller A and Olson E 2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) November 03-08, Macau, China, p. 1898

Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	Jiu-Sheng Li(李九生) and Yi Chen(陈翊). Multi-channel terahertz focused beam generator based on shared-aperture metasurface[J]. 中国物理B, 2023, 32(12): 124204-124204.
[2]	Hua-Kai Sun(孙华锴) and Chang-Kun Chen(陈长坤). Model considering panic emotion and personality traits for crowd evacuation[J]. 中国物理B, 2023, 32(5): 50401-050401.
[3]	Dunwei Peng(彭敦维), Yunpeng Zhang(张云鹏), Xiaolin Tian(田晓林), Hua Hou(侯华), and Yuhong Zhao(赵宇宏). Phase-field-crystal simulation of nano-single crystal microcrack propagation under different orientation angles[J]. 中国物理B, 2023, 32(4): 44601-044601.
[4]	Zheng-Yu Cai(蔡征宇), Ru Zhou(周汝), Yin-Kai Cui(崔银锴), Yan Wang(王妍), and Jun-Cheng Jiang(蒋军成). Simulation based on a modified social force model for sensitivity to emergency signs in subway station[J]. 中国物理B, 2023, 32(2): 20507-020507.
[5]	Yang-Hui Hu(胡杨慧), Yu-Bo Bi(毕钰帛), Jun Zhang(张俊), Li-Ping Lian(练丽萍), Wei-Guo Song(宋卫国), and Wei Gao(高伟). Effect of a static pedestrian as an exit obstacle on evacuation[J]. 中国物理B, 2023, 32(1): 18901-018901.
[6]	Jing Yue(岳靖), Jian Li(李剑), Wen Zhang(张文), and Zhangxin Chen(陈掌星). The coupled deep neural networks for coupling of the Stokes and Darcy-Forchheimer problems[J]. 中国物理B, 2023, 32(1): 10201-010201.
[7]	Min Zhong(仲敏) and Jiu-Sheng Li(李九生). Switchable vortex beam polarization state terahertz multi-layer metasurface[J]. 中国物理B, 2022, 31(11): 114201-114201.
[8]	Jia-Yu Yu(余佳宇), Qiu-Rong Zheng(郑秋容)^†, Bin Zhang(张斌), Jie He(贺杰), Xiang-Ming Hu(胡湘明), and Jie Liu(刘杰). Real-time programmable coding metasurface antenna for multibeam switching and scanning[J]. 中国物理B, 2022, 31(9): 90704-090704.
[9]	Wei-Li Wang(王维莉), Hai-Cheng Li(李海城), Jia-Yu Rong(戎加宇), Qin-Qin Fan(范勤勤), Xin Han(韩新), and Bei-Hua Cong(丛北华). A modified heuristics-based model for simulating realistic pedestrian movement behavior[J]. 中国物理B, 2022, 31(9): 94501-094501.
[10]	Ming-Jian Guo(郭明健), Shu-Kai Duan(段书凯), and Li-Dan Wang(王丽丹). Pulse coding off-chip learning algorithm for memristive artificial neural network[J]. 中国物理B, 2022, 31(7): 78702-078702.
[11]	Guan-Ning Wang(王冠宁), Tao Chen(陈涛), Jin-Wei Chen(陈锦炜), Kaifeng Deng(邓凯丰), and Ru-Dong Wang(王汝栋). Simulation of crowd dynamics in pedestrian evacuation concerning panic contagion: A cellular automaton approach[J]. 中国物理B, 2022, 31(6): 60402-060402.
[12]	Min Zhong(仲敏) and Jiu-Sheng Li(李九生). Multi-function terahertz wave manipulation utilizing Fourier convolution operation metasurface[J]. 中国物理B, 2022, 31(5): 54207-054207.
[13]	Shi-Yu Feng(冯识谕), Yong-Bo Su(苏永波), Peng Ding(丁芃), Jing-Tao Zhou(周静涛), Song-Ang Peng(彭松昂), Wu-Chang Ding(丁武昌), and Zhi Jin(金智). Extrinsic equivalent circuit modeling of InP HEMTs based on full-wave electromagnetic simulation[J]. 中国物理B, 2022, 31(4): 47303-047303.
[14]	Shuqi Xu(徐舒琪), Manuel Sebastian Mariani, and Linyuan Lü(吕琳媛). Modeling the dynamics of firms' technological impact[J]. 中国物理B, 2021, 30(12): 120517-120517.
[15]	Yunhe Tong(童蕴贺), Christopher King, and Yanghui Hu(胡杨慧). Using agent-based simulation to assess diseaseprevention measures during pandemics[J]. 中国物理B, 2021, 30(9): 98903-098903.